#include "language/lexer/variable-parser.h"
#include "libpspp/misc.h"
#include "math/sort.h"
-#include "output/chart-item.h"
#include "output/charts/roc-chart.h"
-#include "output/tab.h"
+#include "output/pivot-table.h"
#include "gettext.h"
#define _(msgid) gettext (msgid)
const struct variable *state_var;
union value state_value;
+ size_t state_var_width;
/* Plot the roc curve */
bool curve;
roc.neg = roc.neg_weighted = 0;
roc.dict = dataset_dict (ds);
roc.state_var = NULL;
+ roc.state_var_width = -1;
lex_match (lexer, T_SLASH);
if (!parse_variables_const (lexer, dict, &roc.vars, &roc.n_vars,
PV_APPEND | PV_NO_DUPLICATE | PV_NUMERIC))
goto error;
- if ( ! lex_force_match (lexer, T_BY))
+ if (! lex_force_match (lexer, T_BY))
{
goto error;
}
roc.state_var = parse_variable (lexer, dict);
+ if (! roc.state_var)
+ {
+ goto error;
+ }
- if ( !lex_force_match (lexer, T_LPAREN))
+ if (!lex_force_match (lexer, T_LPAREN))
{
goto error;
}
- value_init (&roc.state_value, var_get_width (roc.state_var));
+ roc.state_var_width = var_get_width (roc.state_var);
+ value_init (&roc.state_value, roc.state_var_width);
parse_value (lexer, &roc.state_value, roc.state_var);
- if ( !lex_force_match (lexer, T_RPAREN))
+ if (!lex_force_match (lexer, T_RPAREN))
{
goto error;
}
-
while (lex_token (lexer) != T_ENDCMD)
{
lex_match (lexer, T_SLASH);
if (lex_match (lexer, T_LPAREN))
{
roc.reference = true;
- lex_force_match_id (lexer, "REFERENCE");
- lex_force_match (lexer, T_RPAREN);
+ if (! lex_force_match_id (lexer, "REFERENCE"))
+ goto error;
+ if (! lex_force_match (lexer, T_RPAREN))
+ goto error;
}
}
else if (lex_match_id (lexer, "NONE"))
{
if (lex_match_id (lexer, "CUTOFF"))
{
- lex_force_match (lexer, T_LPAREN);
+ if (! lex_force_match (lexer, T_LPAREN))
+ goto error;
if (lex_match_id (lexer, "INCLUDE"))
{
roc.exclude = MV_SYSTEM;
lex_error (lexer, NULL);
goto error;
}
- lex_force_match (lexer, T_RPAREN);
+ if (! lex_force_match (lexer, T_RPAREN))
+ goto error;
}
else if (lex_match_id (lexer, "TESTPOS"))
{
- lex_force_match (lexer, T_LPAREN);
+ if (! lex_force_match (lexer, T_LPAREN))
+ goto error;
if (lex_match_id (lexer, "LARGE"))
{
roc.invert = false;
lex_error (lexer, NULL);
goto error;
}
- lex_force_match (lexer, T_RPAREN);
+ if (! lex_force_match (lexer, T_RPAREN))
+ goto error;
}
else if (lex_match_id (lexer, "CI"))
{
- lex_force_match (lexer, T_LPAREN);
- lex_force_num (lexer);
+ if (!lex_force_match (lexer, T_LPAREN))
+ goto error;
+ if (! lex_force_num (lexer))
+ goto error;
roc.ci = lex_number (lexer);
lex_get (lexer);
- lex_force_match (lexer, T_RPAREN);
+ if (!lex_force_match (lexer, T_RPAREN))
+ goto error;
}
else if (lex_match_id (lexer, "DISTRIBUTION"))
{
- lex_force_match (lexer, T_LPAREN);
+ if (!lex_force_match (lexer, T_LPAREN))
+ goto error;
if (lex_match_id (lexer, "FREE"))
{
roc.bi_neg_exp = false;
lex_error (lexer, NULL);
goto error;
}
- lex_force_match (lexer, T_RPAREN);
+ if (!lex_force_match (lexer, T_RPAREN))
+ goto error;
}
else
{
}
}
- if ( ! run_roc (ds, &roc))
+ if (! run_roc (ds, &roc))
goto error;
- value_destroy (&roc.state_value, var_get_width (roc.state_var));
+ if (roc.state_var)
+ value_destroy (&roc.state_value, roc.state_var_width);
free (roc.vars);
return CMD_SUCCESS;
error:
- if ( roc.state_var)
- value_destroy (&roc.state_value, var_get_width (roc.state_var));
+ if (roc.state_var)
+ value_destroy (&roc.state_value, roc.state_var_width);
free (roc.vars);
return CMD_FAILURE;
}
struct ccase *c;
struct casereader *r = casereader_clone (reader);
- for ( ; (c = casereader_read (r) ); case_unref (c))
+ for (; (c = casereader_read (r)); case_unref (c))
{
int i;
- for (i = 0 ; i < case_get_value_cnt (c); ++i)
- {
- printf ("%g ", case_data_idx (c, i)->f);
- }
+ for (i = 0 ; i < case_get_n_values (c); ++i)
+ printf ("%g ", case_num_idx (c, i));
printf ("\n");
}
#endif
-/*
+/*
Return true iff the state variable indicates that C has positive actual state.
- As a side effect, this function also accumulates the roc->{pos,neg} and
+ As a side effect, this function also accumulates the roc->{pos,neg} and
roc->{pos,neg}_weighted counts.
*/
static bool
{
struct cmd_roc *roc = aux;
const struct variable *wv = dict_get_weight (roc->dict);
- const double weight = wv ? case_data (c, wv)->f : 1.0;
+ const double weight = wv ? case_num (c, wv) : 1.0;
const bool positive =
- ( 0 == value_compare_3way (case_data (c, roc->state_var), &roc->state_value,
+ (0 == value_compare_3way (case_data (c, roc->state_var), &roc->state_value,
var_get_width (roc->state_var)));
- if ( positive )
+ if (positive)
{
roc->pos++;
roc->pos_weighted += weight;
#define N_EQ 1
#define N_PRED 2
-/* Some intermediate state for calculating the cutpoints and the
+/* Some intermediate state for calculating the cutpoints and the
standard error values */
struct roc_state
{
double n2; /* total weight of negatives */
/* intermediates for standard error */
- double q1hat;
+ double q1hat;
double q2hat;
/* intermediates for cutpoints */
double max;
};
-/*
+/*
Return a new casereader based upon CUTPOINT_RDR.
The number of "positive" cases are placed into
the position TRUE_INDEX, and the number of "negative" cases
into FALSE_INDEX.
- POS_COND and RESULT determine the semantics of what is
+ POS_COND and RESULT determine the semantics of what is
"positive".
WEIGHT is the value of a single count.
*/
static struct casereader *
accumulate_counts (struct casereader *input,
- double result, double weight,
+ double result, double weight,
bool (*pos_cond) (double, double),
int true_index, int false_index)
{
struct ccase *cpc;
double prev_cp = SYSMIS;
- for ( ; (cpc = casereader_read (input) ); case_unref (cpc))
+ for (; (cpc = casereader_read (input)); case_unref (cpc))
{
struct ccase *new_case;
- const double cp = case_data_idx (cpc, ROC_CUTPOINT)->f;
+ const double cp = case_num_idx (cpc, ROC_CUTPOINT);
assert (cp != SYSMIS);
/* We don't want duplicates here */
- if ( cp == prev_cp )
+ if (cp == prev_cp)
continue;
new_case = case_clone (cpc);
- if ( pos_cond (result, cp))
- case_data_rw_idx (new_case, true_index)->f += weight;
- else
- case_data_rw_idx (new_case, false_index)->f += weight;
+ int index = pos_cond (result, cp) ? true_index : false_index;
+ *case_num_rw_idx (new_case, index) += weight;
prev_cp = cp;
CUTPOINT_RDR accordingly. TRUE_INDEX and FALSE_INDEX are the indices
which receive these values. POS_COND is the condition defining true
and false.
-
+
3. CC is filled with the cumulative weight of all cases of READER.
*/
static struct casereader *
bool (*pred) (double, double),
const struct dictionary *dict,
double *cc,
- struct casereader **cutpoint_rdr,
+ struct casereader **cutpoint_rdr,
bool (*pos_cond) (double, double),
int true_index,
int false_index)
const int weight_idx = w ? var_get_case_index (w) :
caseproto_get_n_widths (casereader_get_proto (r1)) - 1;
-
+
struct ccase *c1;
struct casereader *rclone = casereader_clone (r1);
proto = caseproto_add_width (proto, 0);
proto = caseproto_add_width (proto, 0);
- wtr = autopaging_writer_create (proto);
+ wtr = autopaging_writer_create (proto);
*cc = 0;
- for ( ; (c1 = casereader_read (r1) ); case_unref (c1))
+ for (; (c1 = casereader_read (r1)); case_unref (c1))
{
struct ccase *new_case = case_create (proto);
struct ccase *c2;
struct casereader *r2 = casereader_clone (rclone);
- const double weight1 = case_data_idx (c1, weight_idx)->f;
- const double d1 = case_data (c1, var)->f;
+ const double weight1 = case_num_idx (c1, weight_idx);
+ const double d1 = case_num (c1, var);
double n_eq = 0.0;
double n_pred = 0.0;
*cc += weight1;
- for ( ; (c2 = casereader_read (r2) ); case_unref (c2))
+ for (; (c2 = casereader_read (r2)); case_unref (c2))
{
- const double d2 = case_data (c2, var)->f;
- const double weight2 = case_data_idx (c2, weight_idx)->f;
+ const double d2 = case_num (c2, var);
+ const double weight2 = case_num_idx (c2, weight_idx);
- if ( d1 == d2 )
+ if (d1 == d2)
{
n_eq += weight2;
continue;
}
- else if ( pred (d2, d1))
+ else if (pred (d2, d1))
{
n_pred += weight2;
}
}
- case_data_rw_idx (new_case, VALUE)->f = d1;
- case_data_rw_idx (new_case, N_EQ)->f = n_eq;
- case_data_rw_idx (new_case, N_PRED)->f = n_pred;
+ *case_num_rw_idx (new_case, VALUE) = d1;
+ *case_num_rw_idx (new_case, N_EQ) = n_eq;
+ *case_num_rw_idx (new_case, N_PRED) = n_pred;
casewriter_write (wtr, new_case);
casereader_destroy (r2);
}
-
+
casereader_destroy (r1);
casereader_destroy (rclone);
/* Some more indeces into case data */
#define N_POS_EQ 1 /* number of positive cases with values equal to n */
-#define N_POS_GT 2 /* number of postive cases with values greater than n */
+#define N_POS_GT 2 /* number of positive cases with values greater than n */
#define N_NEG_EQ 3 /* number of negative cases with values equal to n */
#define N_NEG_LT 4 /* number of negative cases with values less than n */
{
struct ccase *cc = case_create (casewriter_get_proto (writer));
- case_data_rw_idx (cc, ROC_CUTPOINT)->f = cutpoint;
- case_data_rw_idx (cc, ROC_TP)->f = 0;
- case_data_rw_idx (cc, ROC_FN)->f = 0;
- case_data_rw_idx (cc, ROC_TN)->f = 0;
- case_data_rw_idx (cc, ROC_FP)->f = 0;
+ *case_num_rw_idx (cc, ROC_CUTPOINT) = cutpoint;
+ *case_num_rw_idx (cc, ROC_TP) = 0;
+ *case_num_rw_idx (cc, ROC_FN) = 0;
+ *case_num_rw_idx (cc, ROC_TN) = 0;
+ *case_num_rw_idx (cc, ROC_FP) = 0;
casewriter_write (writer, cc);
}
-/*
+/*
Create and initialise the rs[x].cutpoint_rdr casereaders. That is, the readers will
be created with width 5, ready to take the values (cutpoint, ROC_TP, ROC_FN, ROC_TN, ROC_FP), and the
reader will be populated with its final number of cases.
}
caseproto_unref (proto);
- subcase_destroy (&ordering);
+ subcase_uninit (&ordering);
}
for (; (c = casereader_read (r)) != NULL; case_unref (c))
{
for (i = 0 ; i < roc->n_vars; ++i)
{
- const union value *v = case_data (c, roc->vars[i]);
+ const union value *v = case_data (c, roc->vars[i]);
const double result = v->f;
- if ( mv_is_value_missing (var_get_missing_values (roc->vars[i]), v, roc->exclude))
+ if (mv_is_value_missing (var_get_missing_values (roc->vars[i]), v)
+ & roc->exclude)
continue;
minimize (&rs[i].min, result);
maximize (&rs[i].max, result);
- if ( rs[i].prev_result != SYSMIS && rs[i].prev_result != result )
+ if (rs[i].prev_result != SYSMIS && rs[i].prev_result != result)
{
- const double mean = (result + rs[i].prev_result ) / 2.0;
+ const double mean = (result + rs[i].prev_result) / 2.0;
append_cutpoint (rs[i].cutpoint_wtr, mean);
}
{
int i;
- struct roc_state *rs = xcalloc (roc->n_vars, sizeof *rs);
+ struct roc_state *rs = XCALLOC (roc->n_vars, struct roc_state);
struct casereader *negatives = NULL;
struct casereader *positives = NULL;
/* Separate the positive actual state cases from the negative ones */
- positives =
+ positives =
casereader_create_filter_func (input,
match_positives,
NULL,
neg_wtr);
n_proto = caseproto_create ();
-
+
n_proto = caseproto_add_width (n_proto, 0);
n_proto = caseproto_add_width (n_proto, 0);
n_proto = caseproto_add_width (n_proto, 0);
struct casereader *n_pos_reader =
process_positive_group (var, pos, dict, &rs[i]);
- if ( negatives == NULL)
+ if (negatives == NULL)
{
negatives = casewriter_make_reader (neg_wtr);
}
/* Merge the n_pos and n_neg casereaders */
w = sort_create_writer (&up_ordering, n_proto);
- for ( ; (cpos = casereader_read (n_pos_reader) ); case_unref (cpos))
+ for (; (cpos = casereader_read (n_pos_reader)); case_unref (cpos))
{
struct ccase *pos_case = case_create (n_proto);
struct ccase *cneg;
- const double jpos = case_data_idx (cpos, VALUE)->f;
+ const double jpos = case_num_idx (cpos, VALUE);
while ((cneg = casereader_read (n_neg_reader)))
{
struct ccase *nc = case_create (n_proto);
- const double jneg = case_data_idx (cneg, VALUE)->f;
+ const double jneg = case_num_idx (cneg, VALUE);
- case_data_rw_idx (nc, VALUE)->f = jneg;
- case_data_rw_idx (nc, N_POS_EQ)->f = 0;
+ *case_num_rw_idx (nc, VALUE) = jneg;
+ *case_num_rw_idx (nc, N_POS_EQ) = 0;
- case_data_rw_idx (nc, N_POS_GT)->f = SYSMIS;
+ *case_num_rw_idx (nc, N_POS_GT) = SYSMIS;
*case_data_rw_idx (nc, N_NEG_EQ) = *case_data_idx (cneg, N_EQ);
*case_data_rw_idx (nc, N_NEG_LT) = *case_data_idx (cneg, N_PRED);
casewriter_write (w, nc);
case_unref (cneg);
- if ( jneg > jpos)
+ if (jneg > jpos)
break;
}
- case_data_rw_idx (pos_case, VALUE)->f = jpos;
+ *case_num_rw_idx (pos_case, VALUE) = jpos;
*case_data_rw_idx (pos_case, N_POS_EQ) = *case_data_idx (cpos, N_EQ);
*case_data_rw_idx (pos_case, N_POS_GT) = *case_data_idx (cpos, N_PRED);
- case_data_rw_idx (pos_case, N_NEG_EQ)->f = 0;
- case_data_rw_idx (pos_case, N_NEG_LT)->f = SYSMIS;
+ *case_num_rw_idx (pos_case, N_NEG_EQ) = 0;
+ *case_num_rw_idx (pos_case, N_NEG_LT) = SYSMIS;
casewriter_write (w, pos_case);
}
double prev_pos_gt = rs[i].n1;
w = sort_create_writer (&down_ordering, n_proto);
- for ( ; (c = casereader_read (r) ); case_unref (c))
+ for (; (c = casereader_read (r)); case_unref (c))
{
- double n_pos_gt = case_data_idx (c, N_POS_GT)->f;
+ double n_pos_gt = case_num_idx (c, N_POS_GT);
struct ccase *nc = case_clone (c);
- if ( n_pos_gt == SYSMIS)
+ if (n_pos_gt == SYSMIS)
{
n_pos_gt = prev_pos_gt;
- case_data_rw_idx (nc, N_POS_GT)->f = n_pos_gt;
+ *case_num_rw_idx (nc, N_POS_GT) = n_pos_gt;
}
-
+
casewriter_write (w, nc);
prev_pos_gt = n_pos_gt;
}
double prev_neg_lt = rs[i].n2;
w = sort_create_writer (&up_ordering, n_proto);
- for ( ; (c = casereader_read (r) ); case_unref (c))
+ for (; (c = casereader_read (r)); case_unref (c))
{
- double n_neg_lt = case_data_idx (c, N_NEG_LT)->f;
+ double n_neg_lt = case_num_idx (c, N_NEG_LT);
struct ccase *nc = case_clone (c);
- if ( n_neg_lt == SYSMIS)
+ if (n_neg_lt == SYSMIS)
{
n_neg_lt = prev_neg_lt;
- case_data_rw_idx (nc, N_NEG_LT)->f = n_neg_lt;
+ *case_num_rw_idx (nc, N_NEG_LT) = n_neg_lt;
}
-
+
casewriter_write (w, nc);
prev_neg_lt = n_neg_lt;
}
{
struct ccase *prev_case = NULL;
- for ( ; (c = casereader_read (r) ); case_unref (c))
+ for (; (c = casereader_read (r)); case_unref (c))
{
struct ccase *next_case = casereader_peek (r, 0);
- const double j = case_data_idx (c, VALUE)->f;
- double n_pos_eq = case_data_idx (c, N_POS_EQ)->f;
- double n_pos_gt = case_data_idx (c, N_POS_GT)->f;
- double n_neg_eq = case_data_idx (c, N_NEG_EQ)->f;
- double n_neg_lt = case_data_idx (c, N_NEG_LT)->f;
+ const double j = case_num_idx (c, VALUE);
+ double n_pos_eq = case_num_idx (c, N_POS_EQ);
+ double n_pos_gt = case_num_idx (c, N_POS_GT);
+ double n_neg_eq = case_num_idx (c, N_NEG_EQ);
+ double n_neg_lt = case_num_idx (c, N_NEG_LT);
- if ( prev_case && j == case_data_idx (prev_case, VALUE)->f)
+ if (prev_case && j == case_num_idx (prev_case, VALUE))
{
- if ( 0 == case_data_idx (c, N_POS_EQ)->f)
+ if (0 == case_num_idx (c, N_POS_EQ))
{
- n_pos_eq = case_data_idx (prev_case, N_POS_EQ)->f;
- n_pos_gt = case_data_idx (prev_case, N_POS_GT)->f;
+ n_pos_eq = case_num_idx (prev_case, N_POS_EQ);
+ n_pos_gt = case_num_idx (prev_case, N_POS_GT);
}
- if ( 0 == case_data_idx (c, N_NEG_EQ)->f)
+ if (0 == case_num_idx (c, N_NEG_EQ))
{
- n_neg_eq = case_data_idx (prev_case, N_NEG_EQ)->f;
- n_neg_lt = case_data_idx (prev_case, N_NEG_LT)->f;
+ n_neg_eq = case_num_idx (prev_case, N_NEG_EQ);
+ n_neg_lt = case_num_idx (prev_case, N_NEG_LT);
}
}
- if ( NULL == next_case || j != case_data_idx (next_case, VALUE)->f)
+ if (NULL == next_case || j != case_num_idx (next_case, VALUE))
{
rs[i].auc += n_pos_gt * n_neg_eq + (n_pos_eq * n_neg_eq) / 2.0;
rs[i].q1hat +=
- n_neg_eq * ( pow2 (n_pos_gt) + n_pos_gt * n_pos_eq + pow2 (n_pos_eq) / 3.0);
+ n_neg_eq * (pow2 (n_pos_gt) + n_pos_gt * n_pos_eq + pow2 (n_pos_eq) / 3.0);
rs[i].q2hat +=
- n_pos_eq * ( pow2 (n_neg_lt) + n_neg_lt * n_neg_eq + pow2 (n_neg_eq) / 3.0);
+ n_pos_eq * (pow2 (n_neg_lt) + n_neg_lt * n_neg_eq + pow2 (n_neg_eq) / 3.0);
}
casereader_destroy (r);
case_unref (prev_case);
- rs[i].auc /= rs[i].n1 * rs[i].n2;
- if ( roc->invert )
+ rs[i].auc /= rs[i].n1 * rs[i].n2;
+ if (roc->invert)
rs[i].auc = 1 - rs[i].auc;
- if ( roc->bi_neg_exp )
+ if (roc->bi_neg_exp)
{
- rs[i].q1hat = rs[i].auc / ( 2 - rs[i].auc);
- rs[i].q2hat = 2 * pow2 (rs[i].auc) / ( 1 + rs[i].auc);
+ rs[i].q1hat = rs[i].auc / (2 - rs[i].auc);
+ rs[i].q2hat = 2 * pow2 (rs[i].auc) / (1 + rs[i].auc);
}
else
{
casereader_destroy (negatives);
caseproto_unref (n_proto);
- subcase_destroy (&up_ordering);
- subcase_destroy (&down_ordering);
+ subcase_uninit (&up_ordering);
+ subcase_uninit (&down_ordering);
output_roc (rs, roc);
-
+
for (i = 0 ; i < roc->n_vars; ++i)
casereader_destroy (rs[i].cutpoint_rdr);
static void
show_auc (struct roc_state *rs, const struct cmd_roc *roc)
{
- int i;
- const int n_fields = roc->print_se ? 5 : 1;
- const int n_cols = roc->n_vars > 1 ? n_fields + 1: n_fields;
- const int n_rows = 2 + roc->n_vars;
- struct tab_table *tbl = tab_create (n_cols, n_rows);
-
- if ( roc->n_vars > 1)
- tab_title (tbl, _("Area Under the Curve"));
- else
- tab_title (tbl, _("Area Under the Curve (%s)"), var_to_string (roc->vars[0]));
-
- tab_headers (tbl, n_cols - n_fields, 0, 1, 0);
-
-
- tab_text (tbl, n_cols - n_fields, 1, TAT_TITLE, _("Area"));
-
- tab_hline (tbl, TAL_2, 0, n_cols - 1, 2);
-
- tab_box (tbl,
- TAL_2, TAL_2,
- -1, TAL_1,
- 0, 0,
- n_cols - 1,
- n_rows - 1);
+ struct pivot_table *table = pivot_table_create (N_("Area Under the Curve"));
- if ( roc->print_se )
+ struct pivot_dimension *statistics = pivot_dimension_create (
+ table, PIVOT_AXIS_COLUMN, N_("Statistics"),
+ N_("Area"), PIVOT_RC_OTHER);
+ if (roc->print_se)
{
- tab_text (tbl, n_cols - 4, 1, TAT_TITLE, _("Std. Error"));
- tab_text (tbl, n_cols - 3, 1, TAT_TITLE, _("Asymptotic Sig."));
-
- tab_text (tbl, n_cols - 2, 1, TAT_TITLE, _("Lower Bound"));
- tab_text (tbl, n_cols - 1, 1, TAT_TITLE, _("Upper Bound"));
-
- tab_joint_text_format (tbl, n_cols - 2, 0, 4, 0,
- TAT_TITLE | TAB_CENTER,
- _("Asymp. %g%% Confidence Interval"), roc->ci);
- tab_vline (tbl, 0, n_cols - 1, 0, 0);
- tab_hline (tbl, TAL_1, n_cols - 2, n_cols - 1, 1);
+ pivot_category_create_leaves (
+ statistics->root,
+ N_("Std. Error"), PIVOT_RC_OTHER,
+ N_("Asymptotic Sig."), PIVOT_RC_SIGNIFICANCE);
+ struct pivot_category *interval = pivot_category_create_group__ (
+ statistics->root,
+ pivot_value_new_text_format (N_("Asymp. %g%% Confidence Interval"),
+ roc->ci));
+ pivot_category_create_leaves (interval,
+ N_("Lower Bound"), PIVOT_RC_OTHER,
+ N_("Upper Bound"), PIVOT_RC_OTHER);
}
- if ( roc->n_vars > 1)
- tab_text (tbl, 0, 1, TAT_TITLE, _("Variable under test"));
-
- if ( roc->n_vars > 1)
- tab_vline (tbl, TAL_2, 1, 0, n_rows - 1);
-
+ struct pivot_dimension *variables = pivot_dimension_create (
+ table, PIVOT_AXIS_ROW, N_("Variable under test"));
+ variables->root->show_label = true;
- for ( i = 0 ; i < roc->n_vars ; ++i )
+ for (size_t i = 0 ; i < roc->n_vars ; ++i)
{
- tab_text (tbl, 0, 2 + i, TAT_TITLE, var_to_string (roc->vars[i]));
+ int var_idx = pivot_category_create_leaf (
+ variables->root, pivot_value_new_variable (roc->vars[i]));
- tab_double (tbl, n_cols - n_fields, 2 + i, 0, rs[i].auc, NULL);
+ pivot_table_put2 (table, 0, var_idx, pivot_value_new_number (rs[i].auc));
- if ( roc->print_se )
+ if (roc->print_se)
{
- double se ;
- const double sd_0_5 = sqrt ((rs[i].n1 + rs[i].n2 + 1) /
- (12 * rs[i].n1 * rs[i].n2));
- double ci ;
- double yy ;
-
- se = rs[i].auc * (1 - rs[i].auc) + (rs[i].n1 - 1) * (rs[i].q1hat - pow2 (rs[i].auc)) +
- (rs[i].n2 - 1) * (rs[i].q2hat - pow2 (rs[i].auc));
-
+ double se = (rs[i].auc * (1 - rs[i].auc)
+ + (rs[i].n1 - 1) * (rs[i].q1hat - pow2 (rs[i].auc))
+ + (rs[i].n2 - 1) * (rs[i].q2hat - pow2 (rs[i].auc)));
se /= rs[i].n1 * rs[i].n2;
-
se = sqrt (se);
- tab_double (tbl, n_cols - 4, 2 + i, 0,
- se,
- NULL);
-
- ci = 1 - roc->ci / 100.0;
- yy = gsl_cdf_gaussian_Qinv (ci, se) ;
-
- tab_double (tbl, n_cols - 2, 2 + i, 0,
- rs[i].auc - yy,
- NULL);
-
- tab_double (tbl, n_cols - 1, 2 + i, 0,
- rs[i].auc + yy,
- NULL);
-
- tab_double (tbl, n_cols - 3, 2 + i, 0,
- 2.0 * gsl_cdf_ugaussian_Q (fabs ((rs[i].auc - 0.5 ) / sd_0_5)),
- NULL);
+ double ci = 1 - roc->ci / 100.0;
+ double yy = gsl_cdf_gaussian_Qinv (ci, se);
+
+ double sd_0_5 = sqrt ((rs[i].n1 + rs[i].n2 + 1) /
+ (12 * rs[i].n1 * rs[i].n2));
+ double sig = 2.0 * gsl_cdf_ugaussian_Q (fabs ((rs[i].auc - 0.5)
+ / sd_0_5));
+ double entries[] = { se, sig, rs[i].auc - yy, rs[i].auc + yy };
+ for (size_t i = 0; i < sizeof entries / sizeof *entries; i++)
+ pivot_table_put2 (table, i + 1, var_idx,
+ pivot_value_new_number (entries[i]));
}
}
- tab_submit (tbl);
+ pivot_table_submit (table);
}
static void
show_summary (const struct cmd_roc *roc)
{
- const int n_cols = 3;
- const int n_rows = 4;
- struct tab_table *tbl = tab_create (n_cols, n_rows);
-
- tab_title (tbl, _("Case Summary"));
-
- tab_headers (tbl, 1, 0, 2, 0);
-
- tab_box (tbl,
- TAL_2, TAL_2,
- -1, -1,
- 0, 0,
- n_cols - 1,
- n_rows - 1);
-
- tab_hline (tbl, TAL_2, 0, n_cols - 1, 2);
- tab_vline (tbl, TAL_2, 1, 0, n_rows - 1);
-
-
- tab_hline (tbl, TAL_2, 1, n_cols - 1, 1);
- tab_vline (tbl, TAL_1, 2, 1, n_rows - 1);
+ struct pivot_table *table = pivot_table_create (N_("Case Summary"));
+ struct pivot_dimension *statistics = pivot_dimension_create (
+ table, PIVOT_AXIS_COLUMN, N_("Valid N (listwise)"),
+ N_("Unweighted"), PIVOT_RC_INTEGER,
+ N_("Weighted"), PIVOT_RC_OTHER);
+ statistics->root->show_label = true;
- tab_text (tbl, 0, 1, TAT_TITLE | TAB_LEFT, var_to_string (roc->state_var));
- tab_text (tbl, 1, 1, TAT_TITLE, _("Unweighted"));
- tab_text (tbl, 2, 1, TAT_TITLE, _("Weighted"));
+ struct pivot_dimension *cases = pivot_dimension_create__ (
+ table, PIVOT_AXIS_ROW, pivot_value_new_variable (roc->state_var));
+ cases->root->show_label = true;
+ pivot_category_create_leaves (cases->root, N_("Positive"), N_("Negative"));
- tab_joint_text (tbl, 1, 0, 2, 0,
- TAT_TITLE | TAB_CENTER,
- _("Valid N (listwise)"));
-
-
- tab_text (tbl, 0, 2, TAB_LEFT, _("Positive"));
- tab_text (tbl, 0, 3, TAB_LEFT, _("Negative"));
-
-
- tab_double (tbl, 1, 2, 0, roc->pos, &F_8_0);
- tab_double (tbl, 1, 3, 0, roc->neg, &F_8_0);
-
- tab_double (tbl, 2, 2, 0, roc->pos_weighted, 0);
- tab_double (tbl, 2, 3, 0, roc->neg_weighted, 0);
-
- tab_submit (tbl);
+ struct entry
+ {
+ int stat_idx;
+ int case_idx;
+ double x;
+ }
+ entries[] = {
+ { 0, 0, roc->pos },
+ { 0, 1, roc->neg },
+ { 1, 0, roc->pos_weighted },
+ { 1, 1, roc->neg_weighted },
+ };
+ for (size_t i = 0; i < sizeof entries / sizeof *entries; i++)
+ {
+ const struct entry *e = &entries[i];
+ pivot_table_put2 (table, e->stat_idx, e->case_idx,
+ pivot_value_new_number (e->x));
+ }
+ pivot_table_submit (table);
}
-
static void
show_coords (struct roc_state *rs, const struct cmd_roc *roc)
{
- int x = 1;
- int i;
- const int n_cols = roc->n_vars > 1 ? 4 : 3;
- int n_rows = 1;
- struct tab_table *tbl ;
-
- for (i = 0; i < roc->n_vars; ++i)
- n_rows += casereader_count_cases (rs[i].cutpoint_rdr);
-
- tbl = tab_create (n_cols, n_rows);
-
- if ( roc->n_vars > 1)
- tab_title (tbl, _("Coordinates of the Curve"));
- else
- tab_title (tbl, _("Coordinates of the Curve (%s)"), var_to_string (roc->vars[0]));
+ struct pivot_table *table = pivot_table_create (
+ N_("Coordinates of the Curve"));
+ pivot_dimension_create (table, PIVOT_AXIS_COLUMN, N_("Statistics"),
+ N_("Positive if greater than or equal to"),
+ N_("Sensitivity"), N_("1 - Specificity"));
- tab_headers (tbl, 1, 0, 1, 0);
+ struct pivot_dimension *coordinates = pivot_dimension_create (
+ table, PIVOT_AXIS_ROW, N_("Coordinates"));
+ coordinates->hide_all_labels = true;
- tab_hline (tbl, TAL_2, 0, n_cols - 1, 1);
+ struct pivot_dimension *variables = pivot_dimension_create (
+ table, PIVOT_AXIS_ROW, N_("Test variable"));
+ variables->root->show_label = true;
- if ( roc->n_vars > 1)
- tab_text (tbl, 0, 0, TAT_TITLE, _("Test variable"));
- tab_text (tbl, n_cols - 3, 0, TAT_TITLE, _("Positive if greater than or equal to"));
- tab_text (tbl, n_cols - 2, 0, TAT_TITLE, _("Sensitivity"));
- tab_text (tbl, n_cols - 1, 0, TAT_TITLE, _("1 - Specificity"));
-
- tab_box (tbl,
- TAL_2, TAL_2,
- -1, TAL_1,
- 0, 0,
- n_cols - 1,
- n_rows - 1);
-
- if ( roc->n_vars > 1)
- tab_vline (tbl, TAL_2, 1, 0, n_rows - 1);
-
- for (i = 0; i < roc->n_vars; ++i)
+ int n_coords = 0;
+ for (size_t i = 0; i < roc->n_vars; ++i)
{
- struct ccase *cc;
struct casereader *r = casereader_clone (rs[i].cutpoint_rdr);
- if ( roc->n_vars > 1)
- tab_text (tbl, 0, x, TAT_TITLE, var_to_string (roc->vars[i]));
+ int var_idx = pivot_category_create_leaf (
+ variables->root, pivot_value_new_variable (roc->vars[i]));
- if ( i > 0)
- tab_hline (tbl, TAL_1, 0, n_cols - 1, x);
+ struct ccase *cc;
+ int coord_idx = 0;
+ for (; (cc = casereader_read (r)) != NULL; case_unref (cc))
+ {
+ const double se = case_num_idx (cc, ROC_TP) /
+ (case_num_idx (cc, ROC_TP) + case_num_idx (cc, ROC_FN));
+ const double sp = case_num_idx (cc, ROC_TN) /
+ (case_num_idx (cc, ROC_TN) + case_num_idx (cc, ROC_FP));
- for (; (cc = casereader_read (r)) != NULL;
- case_unref (cc), x++)
- {
- const double se = case_data_idx (cc, ROC_TP)->f /
- (
- case_data_idx (cc, ROC_TP)->f
- +
- case_data_idx (cc, ROC_FN)->f
- );
-
- const double sp = case_data_idx (cc, ROC_TN)->f /
- (
- case_data_idx (cc, ROC_TN)->f
- +
- case_data_idx (cc, ROC_FP)->f
- );
-
- tab_double (tbl, n_cols - 3, x, 0, case_data_idx (cc, ROC_CUTPOINT)->f,
- var_get_print_format (roc->vars[i]));
-
- tab_double (tbl, n_cols - 2, x, 0, se, NULL);
- tab_double (tbl, n_cols - 1, x, 0, 1 - sp, NULL);
+ if (coord_idx >= n_coords)
+ {
+ assert (coord_idx == n_coords);
+ pivot_category_create_leaf (
+ coordinates->root, pivot_value_new_integer (++n_coords));
+ }
+
+ pivot_table_put3 (
+ table, 0, coord_idx, var_idx,
+ pivot_value_new_var_value (roc->vars[i],
+ case_data_idx (cc, ROC_CUTPOINT)));
+
+ pivot_table_put3 (table, 1, coord_idx, var_idx,
+ pivot_value_new_number (se));
+ pivot_table_put3 (table, 2, coord_idx, var_idx,
+ pivot_value_new_number (1 - sp));
+ coord_idx++;
}
casereader_destroy (r);
}
- tab_submit (tbl);
+ pivot_table_submit (table);
}
{
show_summary (roc);
- if ( roc->curve )
+ if (roc->curve)
{
struct roc_chart *rc;
size_t i;
show_auc (rs, roc);
- if ( roc->print_coords )
+ if (roc->print_coords)
show_coords (rs, roc);
}